KR100659193B1 - Flexible board connector and connection structure of flexible board to circuit board - Google Patents

Abstract

The casing 2 is arranged in the through hole 41 of the circuit board 40, and the outer contact portion 3b of the contact portion 3 protruding from the adjacent portion of the upper end of the casing 2 is on the upper surface of the circuit board. It is connected to the connecting terminal 43. By inserting the end of the flexible substrate 30 into the insertion opening 9 from the upper hole 6 or the lower hole 7 of the casing 2 by sliding the pressure piece 8 toward the external contact portion 3b side. The inner contact 3a of the contact and the end of the flexible substrate are firmly retained between the thrust block 10 and the pressure piece 8.

Flexible Board Connectors, Casings, Contacts, Clamps, First Holes

Description

FLEXIBLE BOARD CONNECTOR AND CONNECTION STRUCTURE OF FLEXIBLE BOARD TO CIRCUIT BOARD}

1 is a perspective view showing a flexible board connector of one embodiment of the present invention.

2 is a cross-sectional view in a short lateral direction of a flexible board connector located in a circuit board.

3 illustrates a process of connecting a flexible substrate located on an upper side of the circuit board to the circuit board by a flexible board connector.

FIG. 4 illustrates a process of connecting a flexible substrate located on an upper side of the circuit board to the circuit board, continuing from FIG.

FIG. 5 illustrates a process of connecting a flexible substrate located on a lower side of the circuit board to the circuit board by a flexible board connector. FIG.

FIG. 6 illustrates a process of connecting a flexible substrate located on a lower side of the circuit board to the circuit board, continuing from FIG. 5;

Fig. 7 is a plan view showing the components constituting the connecting structure of the flexible board to the circuit board of another embodiment of the present invention.

FIG. 8 is a plan view showing a connection structure of a flexible board to a circuit board composed of the component parts of FIG.

9 illustrates a connection structure of a flexible substrate to a circuit board of the prior art.

Figure 10 illustrates a connection structure of a flexible substrate to a circuit board of the prior art.

Figure 11 illustrates a connection structure of a flexible substrate to a circuit board of the prior art.

<Explanation of symbols for the main parts of the drawings>

1: flexible board connector

2: casing

3, 3a, 3b: conductive contacts

6: upper hole

8: pressure piece

8a: cover part

23: side surface

25, 32: protrusion

30: flexible substrate

31: connection terminal

40: circuit board

41: through hole

43: connection terminal

The present invention relates to a flexible board connector for electrically connecting a flexible board to a circuit board, and more particularly to a connection structure of a flexible board to a circuit board.

In recent years, electronic devices such as mobile phones, video cameras, etc., have internally included a number of built-in electronic components, and are pushing for a reduction in size and weight. Many electronic components have leads and terminals electrically connected by soldering to component mounting lands arranged on a circuit board. In mobile phones where size reduction is being pushed, relatively large components such as LCD modules and keypads are arranged on circuit boards, and a plurality of such circuit boards are often employed. In order to electrically connect the plurality of circuit boards with each other, a plurality of flexible boards are employed. Moreover, flexible substrates are employed to electrically connect other components such as camera modules to circuit boards. Such flexible substrates are sometimes required to be connected from the bottom surface side of the circuit board to connectors arranged with electronic components on the top surface of the circuit board due to design limitations.

From the prior art, the following connecting structure has been adopted to connect the flexible board to the connector of the circuit board from the lower surface side.

(1) As shown in Fig. 9, the circuit board 52, on which the electronic component 51 is arranged, is provided with a connector 53 and a through hole 52a on the upper surface thereof. The flexible substrate 54 is guided from the lower surface side of the circuit board 52 to the upper surface side through the through hole 52a, and the connection portion of the flexible substrate 54 is connected to the connector 53.

(2) As shown in Fig. 10, the connector 63 is provided in the vicinity of a corner portion of the circuit board 62 in which the electronic components 61 are arranged on the upper surface thereof, and the flexible board 64 is provided. The connecting portion of is connected to the connector 63 by bending the flexible substrate 64 so that the substrate covers the edge portion from the lower side side of the circuit board 62.

(3) As shown in Fig. 11, the connector 73 is provided on the lower surface of the circuit board 72 on which the electronic component 71 is arranged on the upper surface thereof, and the flexible substrate on the lower surface side. 74 is connected to the connector 73 without being guided to the upper surface side.

Some of the conventional connectors 53, 63, 73 hold and secure the connection of the flexible substrate between the base fixed to the circuit board and the pivot portion pivotally connected to the base. Moreover, there is a connector fixed to a circuit board, including a coupling pole and a contact terminal, coupling the coupling pole and the coupling pole of the flexible board, and electrically connecting the contact terminal to the connection terminal of the flexible board.

However, the connecting structure of the flexible substrate to the circuit board of the item 1 is subjected to vibration or shock in a state in which the flexible substrate 54 having passed through the through hole 52a is in contact with the edge of the through hole 52a. If accommodated, there is a problem that the wiring portion formed on the flexible substrate 54 is cut by the edges. As a method for solving the above-described problems, a method of chamfering the edge of the through hole 52a, arranging a cover to cover the edge, and a flexible substrate 54 in a shape such that the substrate does not come into contact with the edge or the like. A method of using a jig for molding a) may be considered. However, each method has the problem of causing an increase in cost. Moreover, the connection structure of the flexible board to the circuit board of item 2 has the problem that the limitations on the circuit board design need to be arranged at the corners of the circuit board 52 in addition to the problem similar to that of item (1). Has There is a further problem that the overall length of the flexible substrate 64 is long. The connection structure of the flexible board to the circuit board of the item 3 needs to be arranged on the bottom surface even if the wiring portion for the connector 73 is arranged only on the top surface of the circuit board 72. This has the problem that the cost is increased compared to when electronic components and connectors are arranged on the top surface.

Of particular importance in electronic devices where reductions in size and weight are being driven is reduction in thickness. Thus, as the size and thickness of electronic components and the like decrease, the connector for the flexible substrate also needs to be reduced in size and thickness.

However, the connectors 53, 63, 73 of items (1), (2) and (3) employed for the connection structure of the flexible board to the circuit board are circuit boards 52, 62, 72 according to the prior art. ) Is arranged on the top or bottom surface. Thus, all the connectors 53, 63, 73 protrude from the surface of the circuit boards 52, 62, 72. Thus, this leads to the problem that the circuit boards 52, 62, 72 and the flexible boards 54, 64, 74 in the interconnected state have a relatively large thickness. It may be contemplated to reduce the thickness of components such as insulators, terminals, and the like included in connectors 53, 63, 73. However, this disadvantageously leads to a decrease in structural strength, defective connections and the like.

It is an object of the present invention to provide a flexible board connector which is capable of connecting a flexible board to a circuit board and having a reduced thickness regardless of whether the flexible board is located on the upper surface side or the lower surface side of the circuit board.

In order to achieve the above object, the present invention,

Casing,

A contact having an inner contact located inside the casing and an outer contact projecting outwardly from an adjacent portion of the upper edge on the side surface of the casing;

A clamp partially arranged in the casing and movable relative to the casing, having a clamping surface and movable relative to the casing to narrow the defined insertion opening between the clamping surface and the inner contact of the contact,

A flexible board connector is provided that includes a first hole adjacent to the insertion opening and provided on the bottom surface of the casing.

According to the above-described configuration, the external contact portion of the contact portion is connected to, for example, a connection terminal of a circuit on the circuit board. Moreover, part of the flexible substrate is inserted into an insertion opening formed between the clamping surface of the clamp and the inner contact of the contact, and part of the flexible substrate is clamped by the clamp. With this arrangement, for example, connecting terminals formed in a part of the flexible board are electrically connected to the inner contact portion, and a part of the flexible board is fixed to the flexible board connector.

Furthermore, since the outer contact protrudes from an adjacent portion of the upper edge on the side surface of the casing, the outer contact is connected to a connection terminal or the like located on the upper surface of the circuit board with the casing being disposed in a through hole formed in the circuit board, for example. . That is, the flexible board connector may be electrically connected to the circuit board at least partially overlapping the circuit board in the thickness direction. Thus, the flexible board connector can more effectively reduce the amount of protrusion from the circuit board than in the prior art connectors arranged on the upper surface of the circuit board. As a result, the flexible board connector can be reliably connected to the circuit board while suppressing an increase in the thickness of the circuit board and the flexible board. Moreover, by employing a flexible board connector, the size of the electronic device can be effectively reduced.

Moreover, the flexible board connector is adopted for different flexible boards and circuit boards by forming the outer contact portion in a shape corresponding to the connecting terminal of the circuit board to be connected and the inner contact part in a shape corresponding to the connecting terminal of the flexible board to be connected. do. That is, the flexible board connector, which can be applied to different flexible boards and circuit boards by changing only the shape of the contact portion, has a high flexibility, so that the manufacturing cost can be reduced.

Moreover, a first hole adjacent the insertion opening is provided on the lower surface of the casing. Thus, by arranging the casing in the through hole of the circuit board or by taking similar dimensions, the first hole can be made to face the lower surface of the circuit board. With this arrangement, the flexible substrate located on the lower side of the circuit board can be connected to the circuit board without passing through the through hole provided in the circuit board and bending around the edge of the circuit board unlike the prior art case. Accordingly, the dimensions of the flexible board are to be prevented from cutting the flexible board differently from the prior art, arranging the connector at a desired position without being limited to the edge of the circuit board, and bending around the edge of the circuit board. Eliminate the need to increase. As a result, it is possible to prevent the reduction of the durability of the flexible substrate, to improve the degree of freedom of circuit design of the circuit board, and to prevent the cost increase of the flexible substrate.

In one embodiment, the flexible board connector further includes a second hole adjacent the insertion opening and provided on the upper surface of the casing.

According to this embodiment, the flexible substrate located on the upper side of the casing can be connected to the circuit board, for example through a second hole. Thus, the flexible substrate can be connected to the circuit board regardless of whether the flexible substrate is located on the lower side or the upper side of the casing, thereby obtaining high flexibility. Moreover, the first hole connects the flexible substrate located on the lower side of the casing to the circuit board and the second hole connects the flexible substrate located on the upper side of the casing to the circuit board. That is, the flexible board connector of the present embodiment can connect two flexible boards located on mutually different sides with respect to the casing as one connector to the circuit board.

Furthermore, the connecting structure of the flexible board to the circuit board of one embodiment,

The flexible board connector described above,

A circuit board having a substrate, a circuit formed on the substrate, a connection terminal formed on the substrate and connected to the circuit, and a through hole formed in the substrate adjacent to the connection terminal;

A first flexible substrate having a flexible base, a wiring portion formed on the base, and a connection terminal formed on the base and connected to the wiring portion,

The casing of the flexible board connector is partially disposed in the through hole of the circuit board,

The connecting terminal of the circuit board is connected to the external contact of the contact of the flexible board connector,

The first flexible board has a portion inserted through the first hole of the flexible board connector into the insertion opening of the flexible board connector, the insertion portion is clamped by the clamp, and the connecting terminal is inside the contact portion of the flexible board connector. Is connected to the contact.

According to this configuration, the outer contact portion of the flexible board connector is connected to the connecting terminal of the circuit board with at least a part of the casing of the flexible board connector disposed in the through hole of the circuit board, and the inner contact portion of the flexible board connector is It is connected to the connecting terminal of the flexible board. With this arrangement, the circuit board and the flexible board are connected together with some of the flexible board connectors protruding from the circuit board being smaller than in the case of the prior art. Thus, the connection structure of the flexible substrate to the circuit board has a reduced thickness more effectively than in the case of the prior art. As a result, when the connection structure of the flexible substrate to the circuit board is employed for the electronic device, the electronic device can be effectively reduced in size and thickness.

Moreover, a portion of the flexible substrate is inserted into the insertion opening through the first hole provided on the lower surface of the casing of the flexible board connector. Thus, the flexible substrate located on the lower side of the circuit board is connected to the circuit board without passing through the through hole of the circuit board and bending around the edge of the circuit board unlike the prior art case. Accordingly, the dimensions of the flexible board are prevented from preventing the flexible board from being cut differently from the prior art, arranging a connector in a desired position without being limited to the edge of the circuit board, and bending around the edge of the circuit board. It is possible to eliminate the need to increase. As a result, it is possible to prevent the reduction of the durability of the flexible substrate, to improve the degree of freedom of circuit design of the circuit board, and to prevent the cost increase of the flexible substrate.

In one embodiment, the connecting structure of the flexible substrate to the circuit board is

A second flexible substrate having a flexible base, a wiring portion formed on the base, and a connection terminal formed on the base and connected to the wiring portion,

The flexible board connector has a second hole adjacent the insertion opening and provided on the upper surface of the casing,

A portion of the second flexible board is inserted through the second hole of the flexible board connector into the insertion opening of the flexible board connector, the insertion portion is clamped by the clamp, and the connecting terminal is connected to the inner contact of the contact portion of the flexible board connector. It is configured to be connected.

According to this embodiment, the second flexible substrate is partially inserted into the insertion opening through the second hole of the flexible board connector and connected to the circuit board. Thus, the first flexible substrate and the second flexible substrate located on different sides with respect to the circuit board are connected to the circuit board. Moreover, at least a part of the casing of the flexible board connector is disposed in the through hole of the circuit board, and the amount of protrusion from the circuit board is relatively small. Thus, the connecting structure of two flexible substrates can be obtained while suppressing the increase in thickness.

In one embodiment of the connecting structure of the flexible substrate to the circuit board, the insertion portion of the first flexible substrate and the insertion portion of the second flexible substrate do not overlap with each other in the insertion opening of the flexible board connector. Have the same shape as each other.

According to this embodiment, the first and second flexible substrates are inserted into the insertion openings of the flexible board connector and include portions having shapes that do not overlap each other at the insertion openings and having approximately the same shape. Thus, a flexible substrate having portions of approximately the same shape is connected to the circuit board while arranged on both the upper side and the lower side of the flexible board connector, thereby obtaining high flexibility.

As described above, the flexible board connector of the present invention comprises a casing; A contact having an inner contact located inside the casing and an outer contact projecting outwardly from an adjacent portion of the upper edge on the side surface of the casing; A clamp partially arranged in the casing and movable relative to the casing, the clamp having a clamping surface and capable of narrowing an insertion opening defined between the clamping surface and the inner contact of the contact by moving relative to the casing; And a first hole adjacent the insertion opening and provided on the bottom surface of the casing. Thus, it is possible to arrange the casing in the through hole of the circuit board and insert a part of the flexible substrate from the lower side of the casing through the first opening for electrical and mechanical fixation of the flexible substrate. Thus, the flexible substrate located on the lower side of the circuit board can be connected to the circuit board without causing problems of cutting, length, etc. of the wiring portion and increasing the overall thickness.

The present invention is provided by way of illustration only and will be more fully understood from the following detailed description and accompanying drawings which do not limit the invention.

The invention will be explained in detail below on the basis of the embodiments shown in the drawings.

1 is a perspective view showing the flexible board connector 1 of one embodiment of the present invention. The flexible board connector 1 secures the flexible board 30 to the circuit board 40 and electrically connects the wiring portion of the flexible board 30 to the circuit of the circuit board 40.

The flexible board connector 1 has a substantially rectangular parallelepiped casing 2, and the casing 2 is arranged in a substantially rectangular through hole 41 formed in the circuit board 40. The casing 2 has an upper end that protrudes from the upper surface of the circuit board 40.

The flexible board connector 1 has a plurality of conductive contacts 3 for electrically connecting the circuit of the circuit board 40 to the wiring portion of the flexible board 30.

The contact portions 3 each have an inner contact portion 3a located inside the casing 2 and an outer contact portion 3b located outside the casing 2. The outer contact portion 3b of the contact portion 3 protrudes from the side surface, which is the side surface of the portion of the casing 2 protruding from the upper surface of the circuit board 40, and extends in the longitudinal direction of the casing. The plurality of contacts 3 are arranged in the longitudinal direction of the casing 2 and extend in parallel to each other in the short lateral direction of the casing 2.

The external contact portion 3b of the contact portion 3 is electrically connected by soldering to a connection terminal 43 formed in an adjacent portion of the through hole 41 of the circuit board 40. The connection terminal 43 is connected to a circuit (not shown) of the circuit board 40.

The casing 2 comprises an upper hole 6 as a second hole having on its rectangular shape extending in the longitudinal direction of the upper surface of the casing 2. The upper hole 6 is adjacent to the side surface 23 from which the outer contact 3b of the contact 3 protrudes. The upper hole 6 is adjacent to the insertion opening formed in the casing 2, and the end of the flexible substrate 30 is formed to be inserted into the opening.

On the rear surface at the end of the flexible board 30, that is, the surface facing toward the flexible board connector 1 in FIG. 1, a connecting terminal 31 connected to the wiring portion (not shown) of the flexible board is formed. do. Moreover, two protrusions 32 and 32 protruding in the longitudinal direction of the flexible substrate are provided adjacent to the connecting terminal 31 at all the edges extending in the longitudinal direction of the flexible substrate.

Moreover, two projections 25 are provided on both side surfaces in the short lateral direction of the casing 2 adjacent the side surfaces facing the side surface 23 of the casing 2. do. The protrusion 25 protrudes in the longitudinal direction of the casing 2 and engages with the shallow engagement hole 42 adjacent to the through hole 41 of the circuit board 40. The protrusion 25 is joined to the inner side surface of the coupling hole 42 by soldering or the like, thereby preventing the connector 1 from being displaced and pulled out.

Most of the upper surface of the casing 2 is covered with the upper part of the pressure piece 8 serving as a clamp. The upper part of the pressure piece 8 has a rectangular shape in plan view, and the dimension of the long side is formed to be substantially equal to the dimension in the longitudinal direction of the casing 2. The support extending along the side surface of the casing 2 is adjacent to the short edge of the upper part of the pressure piece 8 and the engagement pawl is formed on the inner side surface of the support. The engagement pawl is engaged with the guide groove 26 formed on the side surface of the casing 2, and the pressure piece 8 is movable in the short lateral direction along the guide groove 26 as indicated by arrow A. Are manufactured. The cover part 8a is formed at the edge of the long side of the upper part of the pressure piece 8, and the cover part 8 is provided with the casing 2 according to the movement of the pressure piece 8 toward the side surface 23 of the casing. Is located above the upper hole 6 of the head.

2 is a cross-sectional view in the short lateral direction of the flexible board connector 1 located in the circuit board 40.

As shown in Fig. 2, the casing 2 has a lower hole 7 which serves as a first hole on its lower surface. The lower hole 7 has a dimension substantially the same as that of the upper hole 6, and is formed on opposite sides in the plan view of the casing 2.

The inner contact 3a of the contact 3 is arranged in the casing 2. The inner contact 3a is adjacent to the outer contact 3b and extends along the inner side surface of the casing 2 and the upper surface of the wedge-shaped thrust block 10 arranged in the casing 2. A contact terminal 3d whose thickness is increased is formed at the end of the inner contact portion 3a of the first contact portion 3. The fixing part 3c extending toward the bottom of the casing 2 is integrally connected to the part located between the inner contacting part 3a and the outer contacting part 3b of the contacting part 3, and the fixing part 3c is connected to the casing. (2) It is engaged with the fixing hole formed inside.

In the casing 2, the insertion opening 9 is a clamping surface 8b, which is the lower surface of the pressure piece 8, an inner contact 3a of the contact 3, an inner surface of the casing 2 and a thrust block 10. Is defined by the top surface. The insertion opening 9 communicates between the upper hole 6 of the casing 2 and the lower hole 7 of the casing. The insertion opening 9 is inclined with respect to the bottom surface of the casing 2. The flexible substrate 30 may be inserted from the upper hole 6 of the casing as indicated by arrow B, and the flexible substrate 30 may be inserted into the insertion opening 9 by the casing as indicated by arrow C. It can be inserted from the lower opening 7 of the.

Below the insertion opening 9 is arranged a slide piece 8c which is formed integrally with the pressure piece 8 and moves together with the pressure piece 8. On the upper surface of the sliding piece 8c, an inclined surface is inclined outwardly toward the outer contact portion 3b side in the sectional view in the short direction of the connector. The thrust block 10 is arranged on the slide piece 8c. The surface of the thrust block 10 positioned in contact with the sliding piece 8c is an inclined surface that slopes downward toward the outer contact portion 3b side. On the other hand, the surface of the thrust block 10 located on the insertion opening 9 side is an inclined surface which inclines upward toward the outer contact portion 3b side. The surface of the thrust block 10 on the insertion opening 9 side and the lower surface of the inner contact portion 3a are located approximately parallel to each other.

3 and 4 illustrate a process of connecting the flexible board 30 positioned on the upper side of the circuit board 40 to the circuit board 40 with the flexible board connector 1.

First, when the cover portion 8a is positioned above the upper hole 6 of the casing, the pressure piece 8 is moved in a direction away from the outer contact portion 3b, and then the upper hole 6 is shown in FIG. It is exposed to the outside as shown. When the pressure piece 8 is moved in a direction away from the outer contact portion 3b, the slide piece 8c is moved away from the outer contact portion 3b together with the pressure piece 8, so that the lower surface is moved by the slide piece ( The thrust block 10 positioned in contact with the inclined top surface of 8c) moves to the bottom surface side of the casing 2.

The end where the connecting terminal 31 of the flexible substrate is formed is inserted into the casing 2 from the exposed upper hole 6. The protrusions 32, 32 formed in the adjacencies of the ends of the flexible substrate 30 are engaged with the edges of the upper hole 6 of the casing, so that the ends of the flexible substrate 30 are casing by a predetermined length. (2) is inserted into. The end of the flexible substrate 30 inserted into the casing 2 is disposed in the insertion opening 9 between the clamping surface 8b of the pressure piece 8 and the inner contact 3.

Next, as shown in Fig. 4, the pressure piece 8 is moved toward the outer contact portion 3b side. By this operation, the clamping surface 8b of the pressure piece 8 presses on the flexible substrate 30. Moreover, the slide piece 8c is moved further with the pressure piece 8 toward the outer contact portion 3b side, and as a result, the thrust block 10 is moved upward. As a result, the upper surface of the thrust block 10 presses the inner contact 3a of the contact 3 upward. As such, the insertion hole 9 is narrowed, and a portion of the flexible substrate 30 and the inner contacting portion 3a of the contact portion are between the clamping surface 8b of the pressure piece 8 and the upper surface of the thrust block 10. Is held in. As a result, the connection terminal 31 of the flexible board 30 and the contact terminal 3d of the contact portion are reliably in contact with each other, thereby achieving electrical and mechanical connection.

As such, the connection structure of the flexible substrate to the circuit board of the present invention is obtained for the flexible substrate 30 located on the upper surface side of the circuit board 40.

5 and 6 illustrate a process of connecting the flexible board 30 positioned on the lower side of the circuit board 40 to the circuit board 40 with the flexible board connector 1.

First, when the cover portion 8a is positioned above the upper hole 6 of the casing, that is, when the insertion hole 9 is narrowed, the pressure piece 8 is moved in a direction away from the outer contact portion 3b, The width of the insertion opening 9 becomes approximately equal to the width of the lower hole 7 of the casing, as shown in FIG.

The end of the flexible substrate located on the lower surface side of the flexible substrate 40 is inserted into the casing 2 from the lower hole 7. The connection terminal 31 is formed at the end of the flexible substrate. The protrusions 32, 32 formed in the adjacencies of the ends are engaged with the edges of the lower holes 7 of the casing, so that the ends of the flexible substrate 30 are inserted into the casing 2 by a predetermined length. The end of the flexible substrate 30 inserted into the casing 2 is disposed in the insertion opening 9 between the clamping surface 8b of the pressure piece 8 and the inner contact 3.

Next, as shown in Fig. 6, the pressure piece 8 is moved to the outer contact portion 3b side. By this operation, the clamping surface 8b of the pressure piece 8 presses on the flexible substrate 30. Moreover, the slide piece 8c is moved together with the pressure piece 8 toward the outer contact portion 3b side, and as a result, the thrust block 10 is moved upward. As a result, the upper surface of the thrust block 10 presses the inner contact 3a of the contact 3 upward. As such, the insertion hole 9 is narrowed, and a part of the flexible substrate 30 and the inner contact portion 3a of the contact portion are between the clamping surface 8b of the pressure piece 8 and the upper surface of the thrust block 10. Is held in. As a result, the connection terminal 31 of the flexible board 30 and the contact terminal 3d of the contact portion are reliably in contact with each other, thereby achieving electrical and mechanical connection.

As such, the connection structure of the flexible substrate to the circuit board of the present invention is obtained for the flexible substrate 30 located on the lower surface side of the circuit board 40.

According to the connection structure of the flexible board to the circuit board, the flexible board connector 1 is connected to the circuit board 40 through the upper hole 6 or the lower hole 7 or the lower side of the circuit board 40. A flexible substrate 40 located on one of the sides can be connected. Accordingly, the flexible substrate 40 located on the lower side of the circuit board 40 does not pass through the through hole of the circuit board and does not bend around the edge of the circuit board as in the case of the prior art. ) Can be connected. As a result, the problem of cutting the flexible board, the problem of increasing the size and length of the flexible board, and the problem of limiting the arrangement position of the flexible board connector can be prevented differently than in the case of the prior art. Moreover, there is no need to guide the connection terminals of the circuit of the circuit board to the bottom surface side to arrange the circuit board connector on the bottom surface of the circuit board. That is, the circuit board is not required to be provided with wiring portions on both sides as wiring portions for circuits on the upper side and wiring portions for connection terminals on the lower side. Therefore, it is possible to prevent the reduction of the durability of the flexible substrate, to improve the degree of freedom of the circuit design of the circuit board, and to prevent the cost increase of the flexible substrate.

Moreover, the flexible board connector 1 attaches the flexible board 30 to the circuit board 40 regardless of whether the flexible board 30 is located on the upper surface side or the lower surface side of the circuit board 40. As it can be connected, high flexibility is obtained. For example, if the flexible board connector 1 is adopted in an electronic device and the flexible board 40 is connected to, for example, an LCD module, a camera module, or the like, the LCD module or camera module is limited in its arrangement position with respect to the circuit board 40. Can be arranged with high degrees of freedom without experiencing.

7 and 8 are plan views showing the components constituting the connection structure of the flexible board to the circuit board of another embodiment of the present invention. The connecting structure of the flexible board of the circuit board of this embodiment is different from the connecting structure of FIGS. 3 to 6 in that the shape of the end portion of the flexible board is composed of the flexible board connector of FIG. In the present embodiment, the same component parts as the above-described embodiments are denoted by the same reference numerals, and no detailed description is provided for this. Although the circuit board 40 is located in the thickness direction between the two flexible substrates 130 and 130 in Figs. 7 and 8, the circuit board 40 is not shown in the figure.

As shown in Fig. 7, the flexible substrate 130 of this embodiment has an end shape to be partially cut away from the center in the width direction. Both flexible substrates 130 and 130 have the same shape. On the other part extending from the center of the flexible board 130, the connection terminal 131 is shown on the lower surface side in Figs. 7 and 8, i.e., the bottom in which the lower hole 7 of the flexible board connector 1 is arranged. It is formed on the side. Furthermore, two protrusions 132 and 132 protruding in the width direction of the flexible substrate adjacent to the connection terminal 131 are provided at edges on both sides extending in the longitudinal direction of the flexible substrate 130.

As shown in Fig. 7, the end of the flexible substrate 130 located on the upper surface side of the circuit board is connected to the casing from the upper hole 6 of the casing of the flexible board connector as indicated by arrow D. 2) inserted into. The end portion of the flexible substrate 130 is inserted into the casing 2 by a predetermined length by joining the corner portions of the upper hole 6 and the protrusions 132 and 132. Furthermore, the end of the flexible substrate 130 located on the lower surface side of the circuit board is inserted into the casing 2 from the lower hole 7 of the casing of the flexible board connector as indicated by arrow E. FIG. The end portion of the flexible substrate 130 is inserted into the casing 2 by a predetermined length by joining the corner portions of the lower hole 7 and the protrusions 132 and 132.

Thus, the ends of the two flexible substrates 130, 130 having the same shape and disposed in the insertion opening 9 opposite to the flexible substrate connector 1 do not overlap each other in the insertion opening 9. Next, by moving the pressure piece 8 of the flexible board connector toward the outer contact portion 3b, the ends of the flexible boards 130, 130 are connected to the clamping surface 8b of the pressure piece 8 and the thrust block ( 10) is retained between the upper surfaces. As a result, the ends of the two flexible boards 130 and 130 are fixed to the circuit board through the flexible board connector 1, and the connecting terminals 131 and 131 of the two flexible boards 130 and 130 are flexible. It is electrically connected to the connecting terminal 43 of the circuit board of the female board connector 1. In this manner, a connection structure between the two flexible substrates 130 and 130 and the circuit board positioned on the upper surface side and the lower surface side of the circuit board is obtained.

As described above, according to the connecting structure of the flexible board to the circuit board of the present embodiment, the ends of the flexible board 130 have shapes such that the ends do not overlap each other in the insertion opening 9 of the flexible board connector. Two flexible substrates 130, 130 fabricated and located on both the top and bottom surface sides of the circuit board may be connected to the circuit board.

The ends of the two flexible substrates 130, 130 located on both the upper and lower surface sides have approximately the same shape in this embodiment, but the ends may have different shapes from each other. For example, the width of the portion where the connection terminal 131 is formed at the end of one flexible substrate 130 and the width of the portion where the connection terminal 131 is formed at the end of the other flexible substrate 130 is formed. It is possible to reduce the It is basically required that the ends have shapes that do not overlap one another in the insertion opening 9 of the flexible board connector 1. The number of connection terminals 131 to be formed at the ends of the flexible substrate may of course vary on the two flexible substrates 130 and 130. Furthermore, the total number of connection terminals 131, 131 of the two flexible boards 130, 130 may be smaller than the total number of contacts 3 of the flexible board connector.

It is possible for the flexible substrate 130 inserted in the upper hole 6 by the cover portion 8a of the pressure bias to extend toward the protrusion side in this embodiment. That is, the elongated protrusion 8a is positioned above the upper hole 6 of the casing 2 and the portion of the flexible substrate 130 located outside the insertion opening 9 of the casing 2 is the pressure piece 8. ) Is thinned toward the upper surface of the casing 2 as it is moved toward the outer contact portion 3b side. With this arrangement, the portion of the flexible substrate 130 located outside the insertion opening 9 can be oriented approximately parallel to the top surface of the circuit board 40 and protruding in a direction away from the circuit board 40. Can be prevented.

Moreover, the flexible board connector 1 of the present embodiment has a casing 2 partially disposed in the through hole 41 of the circuit board, but it is possible to arrange the entire casing in the through hole 41. With this arrangement, the flexible board connector can be manufactured to hardly protrude from the circuit board 40. In such a case, it is appropriate to allow the contacts to extend outward from the upper surface of the casing.

Moreover, the output block 10 in the casing 2 can be removed. In other words, the insertion opening 9 can be narrowed only by the pressure piece 8.

Moreover, the flexible board connector 1 can have only the lower hole 7 without providing the upper hole 6. With this arrangement, the circuit board having the wiring portion for the circuit and the wiring portion for the connection terminal formed only on the upper surface thereof can be connected with the flexible substrate on the lower surface side without providing the double-sided wiring portion.

As mentioned above, it is clear that the present invention can be modified in a number of ways. Such modifications are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be apparent to those skilled in the art are to be construed as falling within the following claims.

According to the present invention, it is possible to provide a flexible board connector which can connect the flexible board to the circuit board and reduce the thickness regardless of whether the flexible board is located on the upper surface side or the lower surface side of the circuit board.

Claims (5)

Casing, A contact having an inner contact located inside the casing and an outer contact projecting outwardly from an adjacent portion of the upper edge on the side surface of the casing; A clamp partially arranged in the casing and movable relative to the casing, having a clamping surface and capable of narrowing the insertion opening formed between the clamping surface and the inner contact of the contact by moving relative to the casing; And a first hole adjacent the insertion opening and provided on the bottom surface of the casing. The flexible board connector of claim 1, further comprising a second hole adjacent the insertion opening and provided on the upper surface of the casing. Is a connecting structure of a flexible board to a circuit board, The flexible board connector according to claim 1, A circuit board having a substrate, a circuit formed on the substrate, a connection terminal formed on the substrate and connected to the circuit, and a through hole formed in the substrate adjacent to the connection terminal; A first flexible substrate having a flexible base, a wiring portion formed on the base, and a connection terminal formed on the base and connected to the wiring portion, The casing of the flexible board connector is partially disposed in the through hole of the circuit board, The connecting terminal of the circuit board is connected to the external contact of the contact of the flexible board connector, The first flexible board has a portion inserted through the first hole of the flexible board connector into the insertion opening of the flexible board connector, the insertion portion is clamped by a clamp, and the connecting terminal is connected to the contact portion of the flexible board connector. Connecting structure connected to the inner contact. The method of claim 3, further comprising a second flexible substrate having a flexible base, a wiring portion formed on the base, and a connection terminal formed on the base and connected to the wiring portion, The flexible board connector has a second hole adjacent the insertion opening and provided on the upper surface of the casing, The second flexible board is inserted into the insertion opening of the flexible board connector, a part of which is inserted through the second hole of the flexible board connector, and the inserted part is clamped by the clamp, and the connecting terminal is connected to the flexible board connector. A connecting structure of a flexible board to a circuit board configured to be connected to an internal contact of a contact. The insert portion of the first flexible substrate and the insert portion of the second flexible substrate have a shape where the insertion portions do not overlap each other in the insertion opening of the flexible substrate connector and have approximately the same shape. Connection structure of a flexible board to a circuit board.

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